basalt/scripts/basalt_response_calib.py

#!/usr/bin/env python3
#
# BSD 3-Clause License
#
# This file is part of the Basalt project.
# https://gitlab.com/VladyslavUsenko/basalt.git
#
# Copyright (c) 2019-2021, Vladyslav Usenko and Nikolaus Demmel.
# All rights reserved.
#

import sys
import math
import os
import cv2
import argparse

import numpy as np
from matplotlib import pyplot as plt

parser = argparse.ArgumentParser(description='Response calibration.')
parser.add_argument('-d', '--dataset-path', required=True, help="Path to the dataset in Euroc format")
args = parser.parse_args()


dataset_path = args.dataset_path

print(dataset_path)

timestamps = np.loadtxt(dataset_path + '/mav0/cam0/data.csv', usecols=[0], delimiter=',', dtype=np.int64)
exposures = np.loadtxt(dataset_path + '/mav0/cam0/exposure.csv', usecols=[1], delimiter=',', dtype=np.int64).astype(np.float64) * 1e-6
pixel_avgs = list()

if timestamps.shape[0] != exposures.shape[0]: print("timestamps and exposures do not match")

imgs = []

# check image data.
for timestamp in timestamps:
    path = dataset_path + '/mav0/cam0/data/' + str(timestamp)
    img = cv2.imread(dataset_path + '/mav0/cam0/data/' + str(timestamp) + '.webp', cv2.IMREAD_GRAYSCALE)
    if len(img.shape) == 3: img = img[:,:,0]
    imgs.append(img)
    pixel_avgs.append(np.mean(img))

imgs = np.array(imgs)
print(imgs.shape)
print(imgs.dtype)


num_pixels_by_intensity = np.bincount(imgs.flat)
print('num_pixels_by_intensity', num_pixels_by_intensity)

inv_resp = np.arange(num_pixels_by_intensity.shape[0], dtype=np.float64)
inv_resp[-1] = -1.0 # Use negative numbers to detect saturation 


def opt_irradiance():
    corrected_imgs = inv_resp[imgs] * exposures[:, np.newaxis, np.newaxis]
    times = np.ones_like(corrected_imgs) * (exposures**2)[:, np.newaxis, np.newaxis]

    times[corrected_imgs < 0] = 0
    corrected_imgs[corrected_imgs < 0] = 0

    denom = np.sum(times, axis=0)
    idx = (denom != 0)
    irr = np.sum(corrected_imgs, axis=0)
    irr[idx] /= denom[idx]
    irr[denom == 0] = -1.0
    return irr

def opt_inv_resp():
    generated_imgs = irradiance[np.newaxis, :, :] * exposures[:, np.newaxis, np.newaxis]
    
    num_pixels_by_intensity = np.bincount(imgs.flat, generated_imgs.flat >= 0)
    
    generated_imgs[generated_imgs < 0] = 0
    sum_by_intensity = np.bincount(imgs.flat, generated_imgs.flat)
    
    new_inv_resp = inv_resp

    idx = np.nonzero(num_pixels_by_intensity > 0)
    new_inv_resp[idx] = sum_by_intensity[idx] / num_pixels_by_intensity[idx]
    new_inv_resp[-1] = -1.0 # Use negative numbers to detect saturation 
    return new_inv_resp 

def print_error():
    generated_imgs = irradiance[np.newaxis, :, :] * exposures[:, np.newaxis, np.newaxis]
    generated_imgs -= inv_resp[imgs]
    generated_imgs[imgs == 255] = 0
    print('Error', np.sum(generated_imgs**2))

for iter in range(5):
    print('Iteration', iter)
    irradiance = opt_irradiance()
    print_error()
    inv_resp = opt_inv_resp()
    print_error()


fig, (ax1, ax2) = plt.subplots(1, 2)
ax1.plot(inv_resp[:-1])
ax1.set(xlabel='Image Intensity', ylabel='Irradiance Value')
ax1.set_title('Inverse Response Function')


ax2.imshow(irradiance)
ax2.set_title('Irradiance Image')
plt.show()
Added Realsense live VIO 2019-06-13 13:37:17 +02:00			`#!/usr/bin/env python3`
ICCV'21 square root marginalization paper code release Major changes: - New square-root implementation for optimization and marginalization, giving faster optimization and numerically more stable marginalization. The square root solver is the new default, but the Schur complement based implementation is still available. (Implements the ICCV'21 paper.) - The odometry estimator is now fully templetized and you can run in float or double. Default is float, which works well with the new square-root implementation and gives best runtimes. - Batch evaluation scripts and documentation to reproduce the ICCV'21 experiments. Additional changes: - New options in VIO to marginalize lost landmark right away and not only when the frame is marginalized (enabled by default). - small bugfix for keypoint patch extraction bounds - basalt_vio: more logging for batch evaluation - basalt_vio: better handling of closing the GUI while estimator is still running - basalt_vio: new command line argument to limit the number of frames processed - basalt_vio: new command line argument to save ground truth trajectory - added unit tests for square root marginalization - update basalt-headers - new submodules: gmt, nlohmann/json, magic_enum 2021-10-15 14:50:02 +02:00			`#`
			`# BSD 3-Clause License`
			`#`
			`# This file is part of the Basalt project.`
			`# https://gitlab.com/VladyslavUsenko/basalt.git`
			`#`
			`# Copyright (c) 2019-2021, Vladyslav Usenko and Nikolaus Demmel.`
			`# All rights reserved.`
			`#`
Added Realsense live VIO 2019-06-13 13:37:17 +02:00
			`import sys`
			`import math`
			`import os`
updated gamma correction script 2019-07-11 18:49:13 +02:00			`import cv2`
small update to scripts 2019-09-13 18:05:25 +02:00			`import argparse`
Added Realsense live VIO 2019-06-13 13:37:17 +02:00
			`import numpy as np`
			`from matplotlib import pyplot as plt`

small update to scripts 2019-09-13 18:05:25 +02:00			`parser = argparse.ArgumentParser(description='Response calibration.')`
			`parser.add_argument('-d', '--dataset-path', required=True, help="Path to the dataset in Euroc format")`
			`args = parser.parse_args()`


			`dataset_path = args.dataset_path`
Added Realsense live VIO 2019-06-13 13:37:17 +02:00
			`print(dataset_path)`

			`timestamps = np.loadtxt(dataset_path + '/mav0/cam0/data.csv', usecols=[0], delimiter=',', dtype=np.int64)`
fix bug 2019-07-11 19:13:03 +02:00			`exposures = np.loadtxt(dataset_path + '/mav0/cam0/exposure.csv', usecols=[1], delimiter=',', dtype=np.int64).astype(np.float64) * 1e-6`
Added Realsense live VIO 2019-06-13 13:37:17 +02:00			`pixel_avgs = list()`

updated gamma correction script 2019-07-11 18:49:13 +02:00			`if timestamps.shape[0] != exposures.shape[0]: print("timestamps and exposures do not match")`

			`imgs = []`
Added Realsense live VIO 2019-06-13 13:37:17 +02:00
			`# check image data.`
			`for timestamp in timestamps:`
			`path = dataset_path + '/mav0/cam0/data/' + str(timestamp)`
small update to scripts 2019-09-13 18:05:25 +02:00			`img = cv2.imread(dataset_path + '/mav0/cam0/data/' + str(timestamp) + '.webp', cv2.IMREAD_GRAYSCALE)`
			`if len(img.shape) == 3: img = img[:,:,0]`
updated gamma correction script 2019-07-11 18:49:13 +02:00			`imgs.append(img)`
Added Realsense live VIO 2019-06-13 13:37:17 +02:00			`pixel_avgs.append(np.mean(img))`

updated gamma correction script 2019-07-11 18:49:13 +02:00			`imgs = np.array(imgs)`
			`print(imgs.shape)`
			`print(imgs.dtype)`

fix irradiance computation 2019-07-12 10:56:47 +02:00

			`num_pixels_by_intensity = np.bincount(imgs.flat)`
			`print('num_pixels_by_intensity', num_pixels_by_intensity)`

			`inv_resp = np.arange(num_pixels_by_intensity.shape[0], dtype=np.float64)`
			`inv_resp[-1] = -1.0 # Use negative numbers to detect saturation`
updated gamma correction script 2019-07-11 18:49:13 +02:00

			`def opt_irradiance():`
			`corrected_imgs = inv_resp[imgs] * exposures[:, np.newaxis, np.newaxis]`
			`times = np.ones_like(corrected_imgs) * (exposures**2)[:, np.newaxis, np.newaxis]`

fix bug 2019-07-11 19:13:03 +02:00			`times[corrected_imgs < 0] = 0`
			`corrected_imgs[corrected_imgs < 0] = 0`

			`denom = np.sum(times, axis=0)`
fix irradiance computation 2019-07-12 10:56:47 +02:00			`idx = (denom != 0)`
			`irr = np.sum(corrected_imgs, axis=0)`
			`irr[idx] /= denom[idx]`
fix bug 2019-07-11 19:13:03 +02:00			`irr[denom == 0] = -1.0`
updated gamma correction script 2019-07-11 18:49:13 +02:00			`return irr`

			`def opt_inv_resp():`
			`generated_imgs = irradiance[np.newaxis, :, :] * exposures[:, np.newaxis, np.newaxis]`

fix bug 2019-07-11 19:13:03 +02:00			`num_pixels_by_intensity = np.bincount(imgs.flat, generated_imgs.flat >= 0)`
fix irradiance computation 2019-07-12 10:56:47 +02:00
			`generated_imgs[generated_imgs < 0] = 0`
updated gamma correction script 2019-07-11 18:49:13 +02:00			`sum_by_intensity = np.bincount(imgs.flat, generated_imgs.flat)`

			`new_inv_resp = inv_resp`

			`idx = np.nonzero(num_pixels_by_intensity > 0)`
			`new_inv_resp[idx] = sum_by_intensity[idx] / num_pixels_by_intensity[idx]`
fix irradiance computation 2019-07-12 10:56:47 +02:00			`new_inv_resp[-1] = -1.0 # Use negative numbers to detect saturation`
			`return new_inv_resp`
updated gamma correction script 2019-07-11 18:49:13 +02:00
			`def print_error():`
			`generated_imgs = irradiance[np.newaxis, :, :] * exposures[:, np.newaxis, np.newaxis]`
			`generated_imgs -= inv_resp[imgs]`
			`generated_imgs[imgs == 255] = 0`
small update to scripts 2019-09-13 18:05:25 +02:00			`print('Error', np.sum(generated_imgs**2))`
updated gamma correction script 2019-07-11 18:49:13 +02:00
fix irradiance computation 2019-07-12 10:56:47 +02:00			`for iter in range(5):`
small update to scripts 2019-09-13 18:05:25 +02:00			`print('Iteration', iter)`
updated gamma correction script 2019-07-11 18:49:13 +02:00			`irradiance = opt_irradiance()`
			`print_error()`
			`inv_resp = opt_inv_resp()`
			`print_error()`


fix bug 2019-07-11 19:13:03 +02:00
Tutorial on photometric and geometric camera-IMU-Mocap calibration with Realsesnse T265 2019-09-30 17:11:22 +02:00			`fig, (ax1, ax2) = plt.subplots(1, 2)`
			`ax1.plot(inv_resp[:-1])`
			`ax1.set(xlabel='Image Intensity', ylabel='Irradiance Value')`
			`ax1.set_title('Inverse Response Function')`


			`ax2.imshow(irradiance)`
			`ax2.set_title('Irradiance Image')`
Added Realsense live VIO 2019-06-13 13:37:17 +02:00			`plt.show()`